Sedimentary ancient DNA shows terrestrial plant richness continuously increased over the Holocene in northern Fennoscandia

The effects of climate change on species richness are debated but can be informed by the past. Here, we generated a sedimentary ancient DNA dataset covering 10 lakes and applied novel methods for data harmonization. We assessed the impact of Holocene climate changes and nutrients on terrestrial plan...

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Bibliographic Details
Published in:Science Advances
Main Authors: Rijal, Dilli P., Heintzman, Peter D., Lammers, Youri, Yoccoz, Nigel G., Lorberau, Kelsey E., Pitelkova, Iva, Goslar, Tomasz, Murguzur, Francisco J. A., Salonen, J. Sakari, Helmens, Karin, Bakke, Jostein, Edwards, Mary E., Alm, Torbjørn, Bråthen, Kari Anne, Brown, Antony G., Alsos, Inger G., anon, anon
Format: Article in Journal/Newspaper
Language:English
Published: Naturhistoriska riksmuseet, Enheten för paleobiologi 2021
Subjects:
Other Earth and Related Environmental Sciences
Annan geovetenskap och miljövetenskap
Arctic
Norway
Climate change
Fennoscandia
Arctic University of Norway
UiT The Arctic University of Norway
Online Access:http://urn.kb.se/resolve?urn=urn:nbn:se:nrm:diva-4575
https://doi.org/10.1126/sciadv.abf9557
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Summary:The effects of climate change on species richness are debated but can be informed by the past. Here, we generated a sedimentary ancient DNA dataset covering 10 lakes and applied novel methods for data harmonization. We assessed the impact of Holocene climate changes and nutrients on terrestrial plant richness in northern Fennoscandia. We find that richness increased steeply during the rapidly warming Early Holocene. In contrast to findings from most pollen studies, we show that richness continued to increase thereafter, although the climate was stable, with richness and the regional species pool only stabilizing during the past three millennia. Furthermore, overall increases in richness were greater in catchments with higher soil nutrient availability. We suggest that richness will increase with ongoing warming, especially at localities with high nutrient availability and assuming that human activity remains low in the region, although lags of millennia may be expected. The study is part of the ECOGEN project “Ecosystem change and species persistenceover time: A genome-based approach,” financed by Research Council of Norway grant 250963/F20. The publication charges for this article have been partially funded by a grant from the publication fund of UiT The Arctic University of Norway

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